Semiconductor device, semiconductor element, and substrate

ABSTRACT

A semiconductor device, a semiconductor element, and a substrate are provided, which allow the semiconductor element to be provided with a reduced size when combined. The semiconductor device has a rectangular semiconductor element mounted on a substrate formed with an external input terminal, an external output terminal, and a plurality of wiring patterns connected to each of the external input terminal and the external output terminal. The semiconductor element includes a grayscale voltage generating unit for generating a plurality of grayscale voltages by dividing a reference voltage, a plurality of electrodes for the reference voltage formed in the neighborhood of the grayscale voltage generating unit; and an internal wiring for connecting the grayscale voltage generating unit and the reference voltage electrodes. The substrate includes a wiring pattern for the reference voltage for connecting the external input terminal and the reference voltage electrodes.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority under 35 USC 119 from Japanese Patent Application No. 2007-226811, the disclosure of which is incorporated by reference herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a semiconductor device, semiconductor element, and a substrate.

2. Description of the Related Art

FIG. 12 shows an example of a configuration of a semiconductor device 100A according to the related art fabricated as a display driver using the COF (Chip On Film) method.

As shown in FIG. 12, the semiconductor device 100A includes a semiconductor element 12 configured as an IC (Integrated Circuit) chip, and an insulating film 18 constituted by a film as a substrate, and the semiconductor element 12 is mounted on the insulating film 18.

The semiconductor element 12 includes a resistance ladder 80 which is formed by series-connected four resistors 80 a, 80 b, 80 c, and 80 d disposed in respective predetermined positions and which generates a reference voltage to serve as a reference for an output voltage to be output from the semiconductor element 12 to a display. The semiconductor element 12 also includes five resistant ladder electrodes 82 a, 82 b, 82 c, 82 d, and 82 e formed along a first edge of the semiconductor element 12. The semiconductor element 12 also includes semiconductor element internal wirings 86 for connecting the resistance ladder electrode 82 a and the resistance ladder electrode 82 e with the ends of the series connection of the resistance ladder 80, and includes a semiconductor element internal wiring 88 for connecting the resistance ladder electrodes 82 b to 82 d with intermediate connecting parts of the series connection of the resistance ladder 80. An Au (gold) bump 84 a, an Au bump 84 b, an Au bump 84 c, an Au bump 84 d, and an Au bump 84 e are provided on a surface of the resistance ladder electrode 82 a, a surface of the resistance ladder electrode 82 b, a surface of the resistance ladder electrode 82 c, a surface of the resistance ladder 82 d, and a surface of the resistance ladder electrode 82 e, respectively.

The insulating film 18 includes input side outer leads 22 and output side outer leads 24 which are provided in a non-mounting region of the insulating film 18 where the semiconductor element 12 is not mounted and which serve as terminals for external connection. The insulating film 18 includes resistance ladder connection nodes 21 a which are formed in a mounting region of the insulating film 18 where the semiconductor element 12 is formed and which are connected to the resistance ladder electrodes 82 a, 82 b, 82 c, 82 d, and 82 d, respectively. The film 18 also includes resistance ladder connection patterns 21 which are formed to extend from a non-mounting region into the mounting region for connecting the input side outer leads 22 and the resistance ladder connection nodes 21 a.

Signals are input to the semiconductor device 100A through the input side outer leads 22 and subjected to predetermined conversion in the semiconductor element 12, and the converted signals are output through the output side outer leads 24. For easier understanding, FIG. 12 shows only the resistance ladder 80 among internal circuits in the semiconductor element 12, and other internal circuits (e.g., a logic unit, a level conversion unit, a latch unit, a D-A conversion unit, and a grayscale voltage generating unit) are omitted in the illustration.

As shown in FIG. 12, in general, the resistance ladder is disposed in a fold configuration because of the dimension of the shorter sides of the semiconductor element 12 and the area to accommodate the same. The resistance ladder shown in FIG. 12 has a circuit configuration as shown in FIG. 13 by way of example. In order to prevent fluctuations of the characteristics of this circuit, the semiconductor element internal wirings 86 and 88 must have low impedance. In particular, the impedance of the semiconductor element internal wirings 86 must be kept as small as possible. For this reason, the line width of the semiconductor element internal wirings 86 and 88 must be great, and a problem has therefore arisen in that the surface area of the semiconductor element 12 must be made great accordingly.

As a technique which can be used as a solution to this problem, Japanese Patent Application Laid-Open No. 2006-80167 has disclosed a technique for reducing the size and weight of a semiconductor device. Specifically, in a semiconductor device wherein a semiconductor element is mounted on a substrate by connecting a wiring pattern formed on the substrate and a first connection terminal formed in a first connection terminal forming region in a peripheral part of the semiconductor element, a second connection terminal form inputting or outputting a signal to or from the semiconductor element is also provided outside the first connection terminal forming region of the semiconductor element. In addition, the substrate is provided with a connection wiring for connecting the second connection terminal with the wiring pattern and/or connecting the second connection terminal with another second connection terminal.

According to this technique, since connection between a circuit in a semiconductor element and a wiring pattern can be provided by a wiring for connection, a wiring which has been routed on or under a surface of the element can be replaced with the connection wiring, which allows the size and weight of the semiconductor element to be reduced.

Although the technique disclosed in the document makes it possible to reduce wirings associated with output from circuits in a semiconductor element, no attention is paid to signals input to a semiconductor element. In particular, the reduction of the size of a semiconductor element is not sufficiently realized when it is attempted based on the existing concept that a first connection terminal is to be formed in a peripheral part of a semiconductor element.

SUMMARY OF THE INVENTION

The invention has been made to solve the above-described problem, and it is an object of the invention to provide a semiconductor device, a semiconductor element, and a substrate a combination of which allow the semiconductor element to be made compact.

A first aspect of the present invention provides a semiconductor device having a rectangular semiconductor element mounted on a substrate formed with an external input terminal, an external output terminal, and a plurality of wiring patterns connected to each of the external input terminal and the external output terminal. The semiconductor element includes a grayscale voltage generating unit for generating a plurality of grayscale voltages by dividing a reference voltage to, a plurality of electrodes for the reference voltage formed in the neighborhood of the grayscale voltage generating unit, and an internal wiring for connecting the grayscale voltage generating unit and the reference voltage electrodes. The substrate includes a wiring pattern for the reference voltage for connecting the external input terminal and the reference voltage electrodes.

The wording “the neighborhood of the grayscale voltage generating unit” means a position where the functional block nearest to the position is the grayscale voltage generating unit.

As thus described, in the semiconductor device in the first aspect of the invention, the semiconductor element includes the reference voltage electrodes provided in the neighborhood of the grayscale voltage generating unit, and the substrate includes the reference voltage wiring pattern for connecting the external input terminal and the reference voltage electrodes. Thus, the semiconductor element can be provided with a reduced size.

A second aspect of the present invention provides a semiconductor device having a rectangular semiconductor element mounted on a substrate formed with an external input terminal, an external output terminal, and a plurality of wiring patterns connected to each of the external input terminal and the external output terminal. The semiconductor element includes a first electrode formed in a plurality of input electrode forming regions provided along a first edge thereof, a second electrode formed along an edge opposite to the first edge, a grayscale voltage generating unit for dividing a reference voltage to generate a plurality of grayscale voltages, a plurality of electrodes for the reference voltage formed in the neighborhood of the grayscale voltage generating unit, and an output unit for outputting a grayscale voltage from the grayscale voltage generating unit selected by a decoder to the second electrode. The substrate includes a first wiring pattern for connecting the external input terminal and the first electrode, a second wiring pattern for connecting the external output terminal and the second electrode, and a wiring pattern for the reference voltage which connects the external output terminal and the reference voltage electrodes, the wiring pattern extending through a region associated with a region having no input electrode formed therein, the region being defined between the input electrode forming regions.

The wording “the neighborhood of the grayscale voltage generating unit” means a position where the functional block nearest to the position is the grayscale voltage generating unit.

As thus described, in the semiconductor device in the second aspect of the invention, the semiconductor element includes the reference voltage electrodes provided in the neighborhood of the grayscale voltage generating unit, and the substrate includes the reference voltage wiring pattern for connecting the external input terminal and the reference voltage electrodes. Thus, the semiconductor element can be provided with a reduced size.

A third aspect of the present invention provides a semiconductor element for forming a part of a semiconductor device that is mounted on a substrate formed with an external input terminal, an external output terminal, and a plurality of wiring patterns connected to each of the external input terminal and the external output terminal. The semiconductor element includes a grayscale voltage generating unit for generating a plurality of grayscale voltages by dividing a reference voltage, a plurality of electrodes for the reference voltage formed in the neighborhood of the grayscale voltage generating unit, and an internal wiring for connecting the grayscale voltage generating unit and the reference voltage electrodes.

The semiconductor element in the third aspect of the invention is identical to the semiconductor element in the first aspect of the invention. Therefore, the third aspect of the invention is advantageous like the first aspect of the invention in that the semiconductor element can be provided with a reduced size when combined with the substrate in the first aspect of the invention.

A fourth aspect of the present invention provides a substrate forming a part of a semiconductor device when a semiconductor element having a grayscale voltage generating unit for dividing a reference voltage to generate a plurality of grayscale voltages, a plurality of electrodes for the reference voltage formed in the neighborhood of the grayscale voltage generating unit, and an internal wiring for connecting the grayscale voltage generating unit and the reference voltage electrodes, is mounted thereon. The substrate includes an external input terminal, an external output terminal, a plurality of wiring patterns connected to each of the external input terminal and the external output terminal, and a wiring pattern for the reference voltage for connecting the external input terminal and the reference voltage electrodes.

The substrate in the fourth aspect of the invention is identical to the substrate in the first aspect of the invention. Therefore, the fourth aspect of the invention is advantageous like the first aspect of the invention in that the substrate can be combined with the semiconductor element in the first aspect to be provided the element with a reduced size.

As described above, the semiconductor device, the semiconductor element, and the substrate according to the invention are advantageous in that they allow the semiconductor element to be provided with a reduced size when combined.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a plan view showing a general configuration of a semiconductor device according to a first embodiment of the invention;

FIG. 2A is a plan view showing a configuration of a part of the semiconductor device according to the first embodiment associated with a ground wiring;

FIG. 2B is a plan view showing a configuration of a part of the semiconductor device according to the first embodiment associated with a power supply wiring;

FIG. 3 is a plan view showing a general configuration of a semiconductor device according to a second embodiment of the invention;

FIG. 4A is a plan view showing a configuration of a part of the semiconductor device according to the second embodiment associated with a ground wiring;

FIG. 4B is a plan view showing a configuration of a part of the semiconductor device according to the second embodiment associated with a power supply wiring;

FIG. 5 is a plan view showing a general configuration of a semiconductor device according to a third embodiment of the invention;

FIG. 6A is a plan view showing a configuration of a part of the semiconductor device according to the third embodiment associated with a ground wiring;

FIG. 6B is a plan view showing a configuration of a part of the semiconductor device according to the third embodiment associated with a power supply wiring;

FIG. 7 is a plan view showing a schematic configuration of a semiconductor device according to a fourth embodiment of the invention;

FIG. 8 is a plan view showing a detailed configuration of the semiconductor device according to the fourth embodiment;

FIG. 9 is a plan view of a modification of the semiconductor device according to the fourth embodiment;

FIG. 10 is a plan view of anther modification of the semiconductor device according to the fourth embodiment; and

FIG. 11 is a plan view showing an example of a combination of a plurality of the embodiments of a semiconductor device.

FIG. 12 is a plan view of an example of a semiconductor device according to the related art; and

FIG. 13 is a circuit diagram showing a circuit configuration of a resistance ladder according to the related art.

DETAILED DESCRIPTION OF THE INVENTION

Embodiments of the invention will now be described in detail with reference to the drawings.

First Embodiment

FIGS. 1, 2A, and 2B show a configuration of a semiconductor device 10A according to the present embodiment which is fabricated as a display driver using the COF (Chip-On-Film) method. FIG. 1 is a plan view showing the configuration of the semiconductor device 1A. FIG. 2A is a plan view showing a configuration of a part of the semiconductor device 10A associated with a ground wiring of the same. FIG. 2B is a plan view showing a configuration of a part of the semiconductor device 10A associated with a power supply wiring of the same.

As shown in FIGS. 1, 2A, and 2B, the semiconductor device 10A includes a semiconductor element 12 configured as an IC (integrated circuit) chip and an insulating film 18 constituted by a film (tape) serving as a substrate, and the device is formed by mounting the semiconductor element 12 on the insulating film 18.

The substantially rectangular semiconductor element 12 has ground terminal electrodes (aluminum pads) 14 a which are electrodes for inputting a ground level formed along a first edge of a surface of the semiconductor element 12, Au (gold) bumps 16 a provided on surfaces of the ground terminal electrodes 14 a, power supply terminal electrodes (aluminum pads) 14 b which are electrodes for power supply input formed along the first edge of the semiconductor element 12, and Au bumps 16 b provided on surfaces of the power supply electrodes 14 b. The ground terminal electrodes 14 a and the power supply terminal electrodes 14 b are referred to using a general term “first electrodes 14”. The semiconductor element 12 also has driver output terminal electrodes (aluminum pads) 25 which are electrodes for outputting signals formed along an edge opposite to the first edge of the semiconductor element 12, Au bumps 26 provided on surfaces of the driver output terminal electrodes 25, a semiconductor element internal ground wiring 28 a, a semiconductor element internal power supply wiring 28 b, and semiconductor element internal output units 30A to 30D which are formed along the edge opposite to the first edge and output respective predetermined signals for driving the display. The semiconductor element internal ground wiring 28 a and the semiconductor element internal power supply wiring 28 b are referred to using a general term “internal power supply wirings 28. The driver output terminal electrodes 25 are also referred to as “second electrodes 25”. The semiconductor element internal ground wiring 28 a and the semiconductor element internal power supply wiring 28 b are provided throughout the semiconductor element 12, and they extend along the edge opposite to the first edge in the neighborhood of semiconductor element internal output units 30.

The insulating film 18 has a mounting region which is defined to allow the semiconductor element 12 to be mounted and a non-mounting region which is defined around the mounting region. Since the semiconductor element 12 is rectangular, the mounting region defined thereon is also rectangular. Particularly, when the element is a driver IC, it has a rectangular shape in most cases, and the direction of the longer sides of the element is therefore defined to be the longitudinal direction thereof.

In the non-mounting region of the insulating film 18, input side outer leads (external input terminals) 22 are formed to allow signals from a control IC (e.g., a timing controller) for controlling the driver IC to be input, and output side outer leads (external output terminals) 24 are also formed such that they are mounted in a display (LCD panel or the like) to allow signals to be output to the same.

In the mounting region of the insulating film 18, first connection nodes 19 a, second connection nodes 20 a, and third connection nodes 54 a are formed.

The first connection nodes 19 a are provided along the first edge which is defined in the rectangular mounting region. The second connection nodes 20 a are provided along the edge opposite to the first edge. Further, the third connection nodes 54 a are provided in the mounting region at an inner side of the first connection nodes 19 a and the second connection nodes 20 a. In the present embodiment, it may be stated that the third connection nodes 54 a is formed in the neighborhood of the second connection nodes 20 a.

Further, metal wiring patterns (first to third connection patterns) 19, 20, and 54 are formed on the insulating film 18. The metal wiring patterns 19 connect the first connection nodes 19 a and the input side outer leads 22. The metal wiring patterns 20 connect the second connection nodes 20 a and the output side outer leads 24. The metal wiring patterns 54 connect the first connection nodes 19 a and the third connection nodes 54 a. The outer leads, the metal wiring patterns, and the connection nodes are integrally formed as occasion demands.

The Au bumps 16 a, 16 b, and 26 are provided on the electrodes 14 a, 14 b, and 26 b which are provided along the periphery of the semiconductor element 12. When the semiconductor element 12 is mounted on the insulating film 18, the Au bumps 16 a and 16 b are electrically connected to the input side outer leads 22 through the metal wiring patterns 19 and the first connection nodes 19 a provided at parts of the metal wiring patterns 19, and the Au bumps 26 are electrically connected to the output side outer leads 24 through the metal wiring patterns 20 and the second connection nodes 20 provided at parts of the metal wiring patterns 20. The first connection nodes 19 a are electrically connected to the Au bumps provided on the semiconductor element 12 and the terminal electrodes where the Au bumps are provided as thus described. Therefore, the connection nodes are formed in the mounting region and are electrically connected to the semiconductor element internal ground wiring 28 a or the semiconductor element internal power supply wiring 28 b.

The terminal electrode provided under each Au bump of the semiconductor element 12 is electrically connected to an internal circuit of the semiconductor element 12 through an internal wiring of the semiconductor element 12.

The ground terminal electrodes 14 a and the power supply terminal electrodes 14 b are electrically connected to the semiconductor element internal ground wiring 28 a and the semiconductor element internal power supply wiring 28 b, respectively. As a result, the semiconductor element internal ground wiring 28 a and the semiconductor element internal power supply wiring 23 b are electrically connected to the input side outer leads 22 through the first connection nodes 20 a and the metal wiring patterns 20.

Signals are input to the semiconductor device 10A through the input side outer leads 22 and are subjected to predetermined conversion in the semiconductor element 12, and the converted signals are output through the output side outer leads 24. In order to avoid confusion, FIGS. 1, 2A, and 2B show only the semiconductor element internal output units 30A to 30D among internal circuits (functional blocks) of the semiconductor element 12, and other internal circuits (such as a logic unit, a level conversion unit, a latch unit, a D-A conversion unit, and a grayscale voltage generating unit) are omitted in the figures.

In general, the semiconductor element internal output units 30A to 30D include operational amplifiers as primary components. The output units may be hereinafter referred to using a general term “semiconductor element internal output units 30”, and the semiconductor element internal output units 30 will now be described.

In general, the semiconductor element internal output unit 30 is provided with operational amplifiers in a quantity equal to or larger than the number of the driver output terminal electrodes 25 associated with the unit. Since there are a great number of driver output terminal electrodes 25, several divisions or blocks such as the semiconductor element internal output units 30A to 30D are provided for reasons associated with designing. In the case of a driver IC having outputs to be provided over 720 channels, since the element has four divisions, operational amplifiers corresponding to 180 channels are provided at the semiconductor element internal output unit 30A. When positive and negative electrodes are to be driven by separate operational amplifiers, operational amplifiers may be formed in a quantity which is several times the number of channels. In this case, the set of operational amplifiers is represented as one output unit. The semiconductor element internal output units 30 are provided in the neighborhood of the driver output terminal electrodes 25.

The semiconductor element internal output unit 30B and the semiconductor element internal output unit 30C are spaced from each other at a distance larger than distances between other combinations of the semiconductor element internal output units 30, and various functional blocks including a grayscale voltage generation circuit are disposed in the space.

The semiconductor element 12 of the present embodiment includes the ground terminal electrodes 52 a and the power supply terminal electrodes 52 b which are formed on a surface of the element and in the neighborhood of the semiconductor element internal output units 30A to 30D. Semiconductor element surface Au bumps 50 a for grounding are formed on the ground terminal electrodes 52 a, and semiconductor element surface Au bumps 50 b for power supply are formed on the power supply terminal electrodes 52 b. The ground terminal electrodes 52 a and the power supply terminal electrodes 52 b may be hereinafter referred to using a general term “third electrodes 52”. The wording “in the neighborhood of the semiconductor element internal output units” means that the electrodes are in positions where the functional blocks nearest to the electrodes are the semiconductor element internal output units or that the electrodes are located around the semiconductor element internal output units.

It may be alternatively put that the third electrodes 52 are provided in the neighborhood of the driver output terminal electrodes 25. In other words, the third electrodes 52 are provided around the semiconductor element internal output units 30. The third electrodes 52 may alternatively be provided between the blocks constituted by the semiconductor element internal output unit 30A and the semiconductor element internal output unit 30B. It is preferable to provide a plurality of the third electrodes 52. Common connection is provided between the plurality of third electrodes 52, i.e., between the ground terminal electrodes 52 a or between the power supply terminal electrodes 52 b by the respective metal wiring patterns 54. A plurality of the third electrodes 52 are provided at positions such as a central part of the semiconductor element 12, the gaps between the blocks constituted by the output units 30, and the neighborhood of the side edges of the surface of the semiconductor element 12, the side edges being the shorter sides of the surface. The third electrodes are preferably provided on each of the left and right longitudinal ends of the semiconductor element 12.

The metal wiring patterns 54 connected to common as described above include parts which are disposed to extend straightly in the longitudinal direction of the element. The metal wiring pattern 54 for common connection between the ground terminal electrodes 52 a and the metal wiring pattern 54 for common connection between the power supply terminal electrodes 52 b are disposed so as to sandwich the semiconductor element internal output units 30. In other words, the output units 30 are located at intervals between the metal wiring pattern 54 for common connection between the ground terminal electrodes 52 a and the metal wiring pattern 54 for common connection between the power supply terminal electrodes 52 b. Further, the metal wiring patterns 54 used for common connection are disposed in the neighborhood of the semiconductor element internal ground wiring 28 a and the semiconductor element internal power supply wiring 28 b. The semiconductor element internal ground wiring 28 a and the semiconductor element internal power supply wiring 28 b are also provided to extend in the longitudinal direction of the element.

The plural ground terminal electrode 14 a and the plural power supply terminal electrode 14 b, which are the first electrodes, are provided along the first side of the semiconductor element 12. In other words, in the longitudinal direction, the ground terminal electrode 14 a and the power supply terminal electrode 14 b are respectively provided on the left and right portions divided along the first side. Here, the power supply terminal electrodes 14 b are disposed closer to the center than the ground terminal electrodes 14 a. Also, the metal wiring patterns 54 connected to the power supply terminal electrodes 14 b are connected to the metal wiring pattern 54 for common connection between the power supply terminal electrodes 52 b via the vicinity of the center portion of the semiconductor element 12.

The ground terminal electrodes 14 a and the ground terminal electrodes 52 a are connected by the semiconductor element internal ground wiring 28 a, and the power supply terminal electrodes 14 b and the power supply terminal electrodes 52 b are connected by the semiconductor element internal power supply wiring 28 b.

The insulating film 18 includes metal wiring patterns 54 formed thereon for electrically connecting the Au bumps 16 a of the semiconductor element 12 and the semiconductor element surface Au bumps 50 a for grounding and for electrically connecting the Au bumps 16 a and the semiconductor element surface Au bumps 50 b for power supply when the semiconductor element 12 is mounted on the film. Therefore, when the semiconductor element 12 is mounted on the insulating film 18, the third connection nodes 54 a provided at parts of the metal wiring patterns 54 is electrically connected to the ground terminal electrodes 52 a or the power supply electrode terminals 52 b. As a result, electrical connection is established between the ground terminal electrodes 14 a and the ground terminal electrodes 52 a and between the power supply terminal electrodes 14 b and the power supply terminal electrodes 52 b. In general, since the metal wiring patterns 54 are formed from a conductive material having a relatively high electrical conductivity such as Cu (copper), resistance provided by the metal wiring patterns 54 is much smaller than that provided by aluminum formed at an inner side of the semiconductor element.

The manufacture of the semiconductor device 10A of the present embodiment will not be described because it can be manufactured using techniques known in the related art including the techniques disclosed in Patent Document 1 by way of example.

In the present embodiment, as thus described, the third electrodes 52 are disposed in the neighborhood of the functional blocks of the semiconductor element 12; the metal wiring patterns 19 and the metal wiring patterns 54 are provided in connection with the input side outer leads 22 provided on the insulating film 18 serving as a substrate; and the metal wiring patterns 54 and the third electrodes 52 are connected. Thus, power can be evenly supplied to the functional blocks. In particular, the third electrodes 52 are disposed in the neighborhood of the semiconductor element internal output units 30 which must have high accuracy, and the third electrodes 52 and the internal power supply wirings 28 are connected. It is therefore possible to maintain paths for supplying power from the first electrodes 14 to the output units 30 through the internal power supply wirings 28 and paths for supplying power from the third electrodes 52 to the output units 30 through the internal power supply wirings 28. Even when the area occupied by the internal power supply wirings 28 is reduced, resistance can be kept substantially unchanged or reduced. Thus, the semiconductor element 12 can be provided with a small surface area by keeping the area of the internal power wirings 28 small, and the performance of the semiconductor element 12 can be satisfactorily kept. The amount of heat generated can be kept small by a substantial reduction in the resistance of the internal power supply wirings 28.

Since the power supply wirings in the semiconductor element 12 are used without any deletion to achieve the above-described effect, it is possible to suppress any variation in characteristics which can otherwise occur when the element is used as a display driver. Thus, there is no need for various adjustments which are otherwise required to cope with such variation in characteristics, which allows designing to be efficiently carried out.

The metal wiring patterns 54 connected to the power supply terminal electrodes 52 b are disposed in the neighborhood of the driver output terminal electrodes 25 and also in the neighborhood of the semiconductor element internal output units 30, fluctuation of the power supply voltage can be suppressed more efficiently. The above-described feature is provided at each of the left and right sides of the semiconductor element 12, and the features are connected to common to allow the resistance of the internal power supply wirings 28 to be reduced further, which enhances the effect of supplying electric power evenly. The present mode for carrying out the invention is made possible by providing the metal wiring patterns 54 so as to extend through the central part of the semiconductor element 12. Further, since the third electrodes 52 are provided in the neighborhood of the semiconductor element internal output units 30 and are connected to each other by the metal wiring patterns 54, the electrodes are expected to play the role of conducting heat from the semiconductor element internal output units 30 which are a source of an especially large amount of heat.

The use of the insulating film 18 having the configuration in the present embodiment allows designing to be carried out efficiently.

Second Embodiment

FIGS. 3, 4A, and 4B show a configuration of a semiconductor device 10B according to a second embodiment of the invention fabricated as a display driver using the COF method. FIG. 3 is a plan view showing the configuration of the semiconductor device 10B. FIG. 4A is a plan view showing a configuration of a part of the semiconductor device 10B associated with a ground wiring of the same. FIG. 4B is a plan view showing a configuration of a part of the semiconductor device 10B associated with a power supply wiring of the same. Components identical between FIGS. 3, 4A, 4B and FIGS. 1, 2A, 2B are indicated by reference numerals used in FIGS. 1, 2A, and 2B and will not be described here.

The semiconductor element 10B has a first connection terminal 62 a and a second connection terminal 62 b which are electrodes for signal input formed along a first edge of a semiconductor element 12, an Au (gold) bump 60 a provided on a surface of the fist connection terminal 62 a, and an Au (gold) bump 60 b provided on a surface of the second connection terminal 62 b. The first connection terminal 62 a and the second connection terminal 62 b are provided in the neighborhood of power supply terminal electrodes 14 b.

Connection nodes 54 b for signal input are formed in a mounting region on an insulating film 18. The connection nodes 54 b for signal input are provided along the first edge of the element.

Further, metal wiring patterns 19 and metal wiring patterns 54 for connecting the connection nodes 54 b for signal input and outer leads 22 for input are formed on the insulating film 18. The input outer leads 22, the metal wiring patterns, and the connection nodes 54 b for signal input may be integrally formed as occasion demands.

The Au bump 60 a and the Au bump 60 b are provided on the first connection terminal 62 a and the second connection terminal 62 b provided along the periphery of the semiconductor element 12. When the semiconductor element 12 is mounted on the insulating film 18, the bumps are electrically connected to the input side outer leads 22 through the metal wiring patterns 19, the metal wiring patterns 54, and the connection nodes 54 b for signal input provided at parts of the metal wiring patterns 54. As thus described, the connection nodes 54 b for signal input are electrically connected to the Au bumps 60 a and 60 b provided at the semiconductor element 12 and the first connection terminal 62 a and the second connection terminal 62 b on which the Au bumps are provided, and the connection nodes are therefore formed in the mounting region.

In the semiconductor element 12, the first connection terminal 62 a and the second connection terminal 62 b provided under the An bumps 60 a and 60 b, respectively are electrically connected to internal circuits of the semiconductor element 12 through internal wirings of the semiconductor element 12.

In the semiconductor device 10B, metal wiring pattern 19 and metal wiring pattern 54 (hereinafter referred to as “left side input signal wiring patterns”) for connecting the connection nodes 54 b for signal input and the input outer leads 22, the first connection terminal 62 a, ground terminal electrodes 52 a, and power supply terminal electrodes 52 b are disposed on the left side of a central part of the semiconductor element when viewed in the longitudinal direction of the element. Metal wiring pattern 19 and metal wiring pattern 54 (hereinafter referred to as “right side input signal wiring patterns”) for connecting the connection nodes 54 b for signal input and the input outer leads 22, the second connection terminal 62 a, ground terminal electrodes 52 a, and power supply terminal electrodes 52 b are disposed on the right side of the central part of the semiconductor element in the longitudinal direction thereof.

On the insulating film 18, the left side input signal wiring patterns and the metal wiring patterns connecting the input outer leads 22 and the ground terminal electrode 14 a and the power supply terminal electrode 14 b located on the left side of the element in the longitudinal direction thereof are disposed in line with each other, and the left side input signal wiring patterns are disposed outside (on the left of) the metal wiring patterns connecting the input outer leads 22 with the ground terminal electrode 14 a and the power supply terminal electrode 14 b located on the left side of the element in the longitudinal direction thereof. The right side input signal wiring patterns and the metal wiring patterns connecting the input outer leads 22 and the ground terminal electrode 14 a and the power supply terminal electrode 14 b located on the right side of the element in the longitudinal direction thereof are disposed in line with each other, and the right side input signal wiring patterns are disposed outside (on the right of) the metal wiring patterns connecting the input outer leads 22 with the ground terminal electrode 14 a and the power supply terminal electrode 14 b located on the right side of the element in the longitudinal direction thereof.

Both of the first connection terminal 62 a and the second connection terminal 62 b are disposed on the first edge closer to the central part than the ground terminal electrode 14 a and the power supply terminal electrode 14 b are. The left side input signal wiring patterns are disposed outside (on the left of) the ground terminal electrode 14 a and the power supply terminal electrode 14 b on the left side of the element in the longitudinal direction thereof with respect to the first edge. The right side input signal wiring patterns are disposed outside (on the right of) the ground terminal electrode 14 a and the power supply terminal electrode 14 b on the right side of the element in the longitudinal direction thereof with respect to the first edge.

On the insulating film 18, the metal wiring pattern connecting the ground terminal electrode 14 a and the ground terminal electrode 52 a on the left side of the element in the longitudinal direction thereof (hereinafter referred to as “left side ground wiring pattern”) and the metal wiring pattern connecting the power supply terminal electrode 14 b and the power supply terminal electrode 52 b on the left side of the element in the longitudinal direction thereof (hereinafter referred to as “left side power supply wiring pattern”) are disposed so as to detour around the left side input signal wiring patterns. The metal wiring pattern connecting the ground terminal electrode 14 a and the ground terminal electrode 52 a on the right side of the element in the longitudinal direction thereof (hereinafter referred to as “right side ground wiring pattern”) and the metal wiring pattern connecting the power supply terminal electrode 14 b and the power supply terminal electrode 52 b on the right side of the element in the longitudinal direction thereof (hereinafter referred to as “right side power supply wiring pattern”) are disposed so as to detour around the right side input signal wiring patterns.

On the insulation film 18, adjustment is made to make impedance provided by the left side ground wiring pattern and the left side power supply wiring pattern and impedance provided by the right side ground wiring pattern and the right side power supply wiring pattern equal to each other.

As shown in FIGS. 3 and 4B, the metal wiring pattern 19 and the metal wiring pattern 54 constituting the left side power supply wiring pattern and the metal wiring pattern 19 and the metal wiring pattern 54 constituting the right side power supply wiring pattern are integrally formed in part and are connected to the power supply terminal electrodes 52 b through the non-mounting region.

In addition to the advantage of the first embodiment, when the configuration of the present embodiment as thus described is used, any difference between the pin layout of an existing driver IC and the pin layout of a panel to which the IC is to be mounted can be handled by designing the substrate appropriately. In other words, the time required for designing the layout of the semiconductor element 12 can be made much shorter than that required in the related art. In particular, the left side ground wiring pattern and the left side power supply wiring pattern detour around the first connection terminal 62 a and the left side input signal wiring patterns, and the right side ground wiring pattern and the right side power supply wiring pattern detour around the second connection terminal 62 b and the right side input signal wiring patterns. Thus, connection can be established between the ground terminal electrodes 52 a and the power supply terminal electrodes 52 b. Since impedance provided by the left side ground wiring pattern and the left side power supply wiring pattern and impedance provided by the right side ground wiring pattern and the right side power supply wiring pattern are made equal, power can be evenly supplied to the left and right sides of the semiconductor element 12 to allow a further reduction of variation in power between pins.

Third Embodiment

FIGS. 5, 6A, and 6B show a configuration of a semiconductor device 10C according to a third embodiment of the invention fabricated as a display driver using the COF method. FIG. 5 is a plan view showing the configuration of the semiconductor device 10C. FIG. 6A is a plan view showing a configuration of a part of the semiconductor device 10C associated with a ground wiring of the same. FIG. 6B is a plan view showing a configuration of a part of the semiconductor device 10C associated with a power supply wiring of the same. Components identical between FIGS. 5, 6A, 6B and FIGS. 1, 2A, 2B are indicated by reference numerals used in FIGS. 1, 2A, and 2B and will not be described here.

In the semiconductor device 10C of the present embodiment, ground terminal electrodes 14 a and power supply terminal electrodes 14 b are alternately disposed along a first edge of the same. Specifically, the ground terminal electrodes 14 a and the power supply terminal electrodes 14 b are disposed to form pairs of adjoining electrodes. Let us assume that a ground terminal electrode 14 a and a power supply terminal electrode 14 b disposed adjacent to each other constitute one power supply electrode pair 15. Then, two power supply electrode pairs 15 are disposed on each of the left and right sides of a central part of the first edge. Referring to the disposition of each set of ground terminal electrode 14 a and power supply terminal electrode 14 b, the power supply terminal electrode 14 b is located closer to the central part of the first edge than the ground terminal electrode 14 a is. Another electrode may be formed between each of the two power supply electrode pairs 15 on the left and right sides. For example, an electrode to which a reference voltage is input may be formed.

On an insulating film 18 of the present embodiment, a metal wiring pattern for connecting the ground terminal electrodes 14 a and ground terminal electrodes 52 a is disposed so as to surround the peripheries of semiconductor element internal output units 30, and a metal wiring pattern for connecting the power supply terminal electrodes 14 b and power supply electrode terminals 52 b is disposed so as to surround the peripheries of the semiconductor element internal output units 30. Specifically, each of the metal wiring patterns is formed by three parts in the left and right sides of a semiconductor element 12 in the longitudinal direction thereof. The left part of the semiconductor element 12 will be described by way of example. The metal wiring pattern in this part is a metal wiring pattern 54 having a first part 31 formed between second electrodes 25 and third electrodes 52 and in the neighborhood of the second electrodes 25 so as to straightly extend in the longitudinal direction of the element, a second part 32 connecting the ground terminal electrode 14 a of one of the two power supply electrode pairs 15 disposed on the left side of the semiconductor element 12 in the longitudinal direction thereof, the electrode pair 15 being closer to a central part 17 of the first edge than the other, to the first part 31 by extending through the central part 17 of the semiconductor element 12, and a third part 33 connecting the ground terminal electrode 14 a of the other of the two power supply electrode pairs 15 disposed on the left side of the semiconductor element 12 in the longitudinal direction thereof to the first part 31 by extending from the mounting region through the non-mounting region. The first, second, and third parts are disposed to surround the peripheries of the output units 30 when combined. The right part of the semiconductor element 12 has similar three parts, and the left and right first parts 31 are connected to common.

In the present embodiment, the same advantages as in the first embodiment can be achieved even in the case of a pin layout in which two power supply electrode pairs are provided on each of the left and right sides of the semiconductor element 12. The metal wiring patterns connecting the ground terminal electrodes 14 a and the ground terminal electrodes 52 a are disposed to surround the peripheries of the semiconductor element internal output units 30, and the metal wiring patterns connecting the power supply terminal electrodes 14 b and the power supply terminal electrodes 52 b are also disposed to surround the peripheries of the semiconductor element internal output units 30. Therefore, power can be evenly supplied, and a further reduction can be achieved in variation of power between pins.

Fourth Embodiment

FIG. 7 shows a schematic configuration of a semiconductor device 10D according to a fourth embodiment of the invention fabricated as a display driver using the COF method. Components identical between FIG. 7 and FIG. 1 are indicated by reference numerals used in FIG. 1 and will not be described here.

As shown in FIG. 7, the semiconductor device 10D of the present embodiment has a voltage generating unit 90 which is provided substantially in the middle of a semiconductor element 12 when viewed in the longitudinal direction of the element.

The voltage generating unit 90 generates a plurality of grayscale voltages by dividing a reference voltage applied through input side outer leads 22, a connection pattern 21 for a resistance ladder, and a metal pattern 54 using the resistance ladder.

In the semiconductor device 10D of the present embodiment, a terminal electrode is provided in the neighborhood of the resistance ladder instead of providing a terminal electrode for the resistance ladder in a peripheral part of the semiconductor element 12. The terminal electrode and the input side outer leads 22 are directly connected to an insulating film 18 through the connection pattern 21 for the resistance ladder and the metal pattern 54. Thus, the semiconductor element 12 can be provided with a size smaller than that in the case that the terminal electrode for the resistance ladder is provided at a peripheral part of the semiconductor element 12.

Each of decoders 31A to 31D shown in FIG. 7 is associated with any of semiconductor element internal output units 30A to 30D in a one-to-one relationship, and the decoders generate signals to be used by the respective semiconductor element internal output units using grayscale voltages generated by the voltage generating unit 90.

FIG. 8 shows a detailed configuration of the voltage generating unit 90. Components identical between FIG. 8 and FIG. 1 are indicated by the reference numerals used in FIG. 1 and will not be described here.

As shown in FIG. 8, the voltage generating unit 90 includes a resistance ladder 80 which is formed by series-connecting resistors 80 a, 80 b, 80 c, and 80 d disposed in respective predetermined positions and which generates a grayscale voltage to serve as a reference for an output voltage to be output from the semiconductor element 12 to a display.

The voltage generating unit 90 includes five resistance ladder electrodes 82 a, 82 b, 82 c, 82 d, and 82 e formed in the neighborhood of the resistance ladder 80. The voltage generating unit 90 also includes semiconductor element internal wirings 86 for connecting the resistance ladder electrode 82 a and the resistance ladder electrode 82 e with the ends of the series connection of the resistance ladder 80 and includes a semiconductor element internal wiring 88 for connecting the resistance ladder electrodes 82 b to 82 d with intermediate connecting parts of the series connection of the resistance ladder 80. An Au (gold) bump 84 a, an Au bump 84 b, an Au bump 84 c, an Au bump 84 d, and an Au bump 84 e are provided on a surface of the resistance ladder electrode 82 a, a surface of the resistance ladder electrode 82 b, a surface of the resistance ladder electrode 82 c, a surface of the resistance ladder 82 d, and a surface of the resistance ladder electrode 82 e, respectively.

The insulating film 18 includes resistance ladder connection nodes 21 a which are formed in a mounting region and connected to the resistance ladder electrodes 82 a, 82 b, 82 c, 82 d, and 82 d, respectively, and resistance ladder connection patterns 21 and metal wiring patterns 54 which are formed to extend from a non-mounting region into the mounting region for connecting the input side outer leads 22 and the resistance ladder connection nodes 21 a.

Signals are input to the semiconductor device 10D through the input side outer leads 22 and subjected to predetermined conversion in the semiconductor element 12, and the converted signals are output through output side outer leads 24. In order to avoid confusion, FIG. 8 shows only the resistance ladder 80 among circuits in the semiconductor element 12, and other internal circuits (e.g., a logic unit, a level conversion unit, a latch unit, a D-A conversion unit, and a grayscale voltage generating unit) are omitted in the illustration.

As thus described, in the present embodiment, the Au bumps 84 a to 84 e and the resistance ladder electrodes 82 a to 82 e provided under the respective bumps are disposed in the neighborhood of the resistance ladder 80 in connection with the respective resistors, and the metal wiring patterns 54 on the semiconductor element are routed to make a detour such that the state of connection between the input side outer leads 22 and the Au bumps 84 a to 84 e will not be changed. Thus, the physical distance between the resistance ladder 80 and the Au bumps 84 a to 84 e can be kept small, and the impedance of the semiconductor element internal wirings 86 and the semiconductor element internal wiring 88 can be made small. As a result, the semiconductor element internal wirings 86 and the semiconductor element internal wiring 88 can be laid to occupy a small area. That is, the surface area of the semiconductor element 12 can be made small. In other words, a reference voltage input to the voltage generating unit 90 for generating voltages to serve as a basis for voltages output by the semiconductor element internal output units 30 can be supplied with less fluctuation. Further, the contribution to reduction in the wiring area in the semiconductor element allows the surface area of the semiconductor element to be reduced.

The invention has been described above with reference to embodiments of the same, but the technical scope of the invention is not limited to the above description of the embodiments. The embodiments may be variously altered or modified without departing from the spirit of the invention, and such alterations and modifications are also included in the technical scope of the invention.

The above-described embodiments are not limiting the invention set forth in the appended claims, and not all combinations of the features described in the embodiments constitute essential solving means of the invention. The above-described embodiments include various aspects of the invention, and it is therefore possible to extract the various aspects of the invention by combining the plurality of constituent features disclosed herein appropriately. Even when some of the constituent features disclosed in the embodiments are deleted, the configuration lacking those constituent features can be still extracted as an aspect of the invention as long as it provides the advantages of the invention.

For example, the fourth embodiment has been described as a case in which a semiconductor device 10D as shown in FIG. 8 is used as a semiconductor device according to the invention by way of example. The invention is not limited to the same, and the device may be replaced by, for example, a semiconductor device 10E as shown in FIG. 9 or a semiconductor device 10F as shown in FIG. 10. FIG. 10 is different from FIGS. 8 and 9 in that reference voltage input electrodes 83 are provided. It is desirable to exclude the reference voltage input electrodes 83 because the surface area of the device can be smaller when there is no need for the area to accommodate the electrodes 83, and FIG. 10 may be understood as showing that the possibility of the provision of such electrodes is not eliminated where they are required. In FIGS. 9 and 10, the elements having the same functions as those shown in FIG. 8 are given the same reference numerals as in FIG. 8. The same advantages as those of the fourth embodiment can be achieved also in these cases.

Obviously, the first to fourth embodiments may be implemented in combination.

FIG. 11 shows an example of a configuration of a semiconductor device which is a combination of the third and fourth embodiments. Although FIG. 11 shows no tape substrate, it is assumed that all wirings shown in the figure are formed on a tape substrate.

As shown in FIG. 11, in this exemplary configuration, two voltage generating units 90, i.e., a voltage generating unit 90A and a voltage generating unit 90B are provided. Details of the voltage generating units 90 are as shown in FIGS. 8 to 10. A region 92 between the voltage generating unit 90A and the voltage generating unit 90B is a region where functional blocks excluding output units 30 and the voltage generating units 90 are disposed.

Each of semiconductor element internal output units 30A to 30D outputs a grayscale voltage which has been selected by either P decoder constituted by a P-channel MOSFET or N decoder constituted by an N-channel MOSFET. The voltage generating unit 90A generates grayscale voltages to be input to the decoder constituted by a P-channel MOSFET, and the voltage generating unit 90B generates grayscale voltages to be input to the decoder constituted by an N-channel MOSFET.

In the case of a driver capable of displaying eight bits of data (256 grayscales), each of the voltage generating units 90A and 90B generates voltages to render 256 grayscales, and nine or eleven reference voltages are supplied to each unit.

The semiconductor element 12 includes three types of regions provided along a first edge of the same, i.e., regions 98A having output electrode formed therein, regions 98B having input electrodes formed therein, and regions 98C having no input electrode formed therein. The regions 98C without input electrode are provided between the input electrode regions 98B. Particularly, the regions 98C without input electrode are provided between first electrodes (ground terminal electrodes or power supply terminal electrodes) provided at the input electrode regions 98B. In this case, an input side outer lead and an electrode 82 for a resistance ladder are connected by a metal wiring pattern 54 (VGMA) through a region on the substrate associated with a region 98C without input electrode.

Metal wiring patterns 54 shown in FIG. 11 have unique shapes. A structure of a metal wiring pattern 54 (Vdd) connecting power supply terminal electrodes 14 a and power supply terminal electrodes 52 will now be particularly described. The metal wiring pattern 54 (Vdd) is constituted by a common connection unit 94 for connecting each of the power supply terminal electrodes 52 disposed in the neighborhood of an output unit 30 in common and an impedance adjusting unit 96 for connecting the power supply terminal electrodes 14 a and the common connection unit 94 to adjust the impedance of the internal power supply wiring. The impedance adjusting unit 96 is connected to the common connection unit 94 at a point close to the power supply terminal electrode 52 a closest to a corner of the semiconductor element 12 instead of connecting them by the shortest route. In other words, the point of connection to the common connection unit 94 is made close to the output unit 30D (or the output unit 30A on the left side of the semiconductor element 12) among the output units 30 which is located at a longitudinal end of the semiconductor element 12. The use of this configuration allows the supply of power to be kept a higher level of evenness between the output units 30C and 30D.

The first and fourth embodiments can be implemented in a combined form as shown in FIG. 11 by providing wiring patterns 54 corresponding to those in the first embodiment using either of the two power supply electrode pairs disposed on the left and right sides of the semiconductor element 12.

Similarly, a plurality of embodiments among the first to third embodiments may be implemented in combination. In such a case, the combined embodiment has all advantages provided by the original embodiments.

The numbers of various Au bumps shown in the above-described embodiments are merely examples, and the bumps may obviously be provided in different quantities. The same advantages as those of the above embodiments can be achieved also in such a case.

Although no particular mention has been made of display apparatus to which the embodiments apply, the invention can be used for various displays including liquid crystal displays, plasma displays, and organic EL displays.

While the above embodiments have been described as cases wherein Au is used as the material of bumps, other metals may obviously be used instead.

The first to third embodiments have been described as cases wherein a semiconductor element internal output unit is divided into four blocks, i.e., semiconductor element internal output units 30A to 30D. The invention is not limited to such a configuration, and the output unit may obviously be divided into a different number of blocks. The same advantages as those of the above embodiments can be achieved also in such a case.

The fourth embodiment has been described as a case wherein a resistance ladder is divided into four blocks. The invention is not limited to such a configuration, and the resistance ladder may obviously be divided into a different number of blocks. The same advantages as those of the fourth embodiment can be achieved also in such a case.

A semiconductor device and a substrate according to the invention are advantageous in that a semiconductor element can be made compact and designed efficiently while maintaining the performance of the element, in particular, power supplying capability. 

1. A semiconductor device having a rectangular semiconductor element mounted on a substrate formed with an external input terminal, an external output terminal, and a plurality of wiring patterns connected to each of the external input terminal and the external output terminal, wherein the semiconductor element comprises: a grayscale voltage generating unit for generating a plurality of grayscale voltages by dividing a reference voltage; a plurality of electrodes for the reference voltage formed in a neighborhood of the grayscale voltage generating unit; an internal wiring for connecting the grayscale voltage generating unit and the reference voltage electrodes; a plurality of first electrodes formed along a first edge of the semiconductor element; a plurality of second electrodes formed along an edge of the semiconductor element opposite to the first edge; a plurality of third electrodes formed in a neighborhood of a functional block; and an internal wiring for connecting the first electrodes and the third electrodes, and wherein the substrate comprises a wiring pattern for the reference voltage for connecting the external input terminal and the reference voltage electrodes; a first wiring pattern for connecting the external input terminal and the first electrodes; a second wiring pattern for connecting the external output terminal and the second electrodes; and a third wiring pattern for connecting the first electrodes and the third electrodes, wherein the semiconductor element further comprises a signal input electrode formed in a neighborhood of the first electrodes and along the first edge, and the substrate further comprises an input signal wiring pattern for connecting the signal input electrode and the external input terminal, wherein the first wiring pattern and the input signal wiring pattern are disposed in a line, the input signal wiring pattern is disposed at an outer side of the first wiring pattern, the signal input electrode is disposed closer to a central part of the first edge than the first electrodes, the input signal wiring pattern connects to the signal input electrode via an outer side of the first electrodes as viewed from the first edge, and the third wiring pattern detours around the input signal wiring pattern and is connected to the third electrodes.
 2. A semiconductor device having a rectangular semiconductor element mounted on a substrate formed with an external input terminal, an external output terminal, and a plurality of wiring patterns connected to each of the external input terminal and the external output terminal, wherein the semiconductor element comprises: a grayscale voltage generating unit for generating a plurality of grayscale voltages by dividing a reference voltage; a plurality of electrodes for the reference voltage formed in a neighborhood of the grayscale voltage generating unit; an internal wiring for connecting the grayscale voltage generating unit and the reference voltage electrodes; a plurality of first electrodes formed along a first edge of the semiconductor element; a plurality of second electrodes formed along an edge of the semiconductor element opposite to the first edge; a plurality of third electrodes formed in a neighborhood of a functional block; and an internal wiring for connecting the first electrodes and the third electrodes, and wherein the substrate comprises a wiring pattern for the reference voltage for connecting the external input terminal and the reference voltage electrodes; a first wiring pattern for connecting the external input terminal and the first electrodes; a second wiring pattern for connecting the external output terminal and the second electrodes; and a third wiring pattern for connecting the first electrodes and the third electrodes, wherein the plurality of first electrodes include a first power supply electrode and a first ground electrode, a plurality of at least either first power supply electrodes or first ground electrodes being provided, and the first power supply electrode and the first ground electrode being disposed alternately, and the third wiring pattern connects the plurality of first power supply electrodes or first ground electrodes with the third electrodes, the third wiring pattern being disposed to surround the periphery of the functional block.
 3. A semiconductor device having a rectangular semiconductor element mounted on a substrate formed with an external input terminal, an external output terminal, and a plurality of wiring patterns connected to each of the external input terminal and the external output terminal, wherein the semiconductor element comprises: a first electrode formed in a plurality of input electrode forming regions provided along a first edge of the semiconductor element; a second electrode formed along an edge of the semiconductor element opposite to the first edge; a grayscale voltage generation unit for generating a plurality of grayscale voltages by dividing a reference voltage; a plurality of electrodes for the reference voltage formed in a neighborhood of the grayscale voltage generation unit; and an output unit for outputting a grayscale voltage from the grayscale voltage generation unit selected by a decoder to the second electrode, and wherein the substrate comprises a first wiring pattern for connecting the external input terminal and the first electrode; a second wiring pattern for connecting the external output terminal and the second electrode; and a wiring pattern for the reference voltage which connects the external output terminal and the reference voltage electrodes, the wiring pattern extending through a region associated with a region having no input electrode formed therein, the region being defined between the input electrode forming regions, wherein the neighborhood of the grayscale voltage generation unit is defined as an area in which a distance between the reference voltage electrodes and the grayscale voltage generation unit is smaller than a distance between the first electrode and the grayscale voltage generation unit. 